p-rich beams for SPES-α

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Kathleen Lamb
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1 p-rich beams for SPES-α LNL-INFN

2 The SPES TIS complex ion source 1+ transfer line proton beam SPES production target

3 The Target: ready for irradiation ITarget= 700A -> 1200A max ILine= 200A -> 600A max

The isotope release Release of isotopes from a ISOL target: involved processes The target yield and release efficiency Y Target = Φ σ N ε R f= Injector flux, s = Cross section N= Target thickness, e

4 The isotope release Release of isotopes from a ISOL target: involved processes The target yield and release efficiency Y Target = Φ σ N ε R f= Injector flux, s = Cross section N= Target thickness, e R = Release efficiency e R takes into account the efficiencies of all the involved processes ε R = e diffusion e effusion e ionization e transport 1. In-target reaction (fission) 2. In-target diffusion 3. Effusion from target to ion source 4. Ionization 5. Acceleration and transport Most critical processes for release efficiency, they are affected by: 1) Material composition and density 2) Material microstructural properties (grain size,porosity, interconnectivity) 3) Working Temperature (use of high limiting temperature materials)

5 Yield (/sec/ A) Temperature vs yield Spes data from HRIBF measurement 10 8 Br T very important for short lived isotopes! T 1/2 (s) Br yields 2000 C Br yields 1800 C Br yields 1600 C

6 First conclusion Is necessary to produce for SPES RIB: 1) Target with high working temperature -> refractory carbides/oxides 2) Material with good characteristics in terms of release (grain and porosity) -> carefully R&D is mandatory!

7 Target: n-rich vs. p-rich 1 target material (UCx), & many isotopes produced on it Dedicated material (carbides), & few isotopes produced in each Density (g/cm³) Diameter (mm) Thickness (g/cm²) Calculated porosity (%)

La 2 O 3 + 11C 2LaC 2 + 4C + 3CO OXIDE +

8 Lanthanum carbide synthesis Vertical Carbothermic reduction (1600 C, high vacuum) La 2 O C 2LaC 2 + 4C + 3CO OXIDE + GRAPHITE GREEN PELLETS CARBIDE/GRAPHITE (LaCx) PELLETS

citric acid C 6 H 8 O 7 Solution of the acid Gel formation

treatment : up to 800 C in low vacuum (5*10-2 mbar), 0.

C/min 2 hours at 1500 C B(OH) 3 + CITRIC ACID 2.

(35-0798) B 4 C formation after primary thermal treatment

9 I (u.a.) I (u.a.) Boron carbide (B 4 C) production Boric acid B(OH) 3 + citric acid C 6 H 8 O 7 Solution of the acid Gel formation Grounding Thermal treatment High T sintering Thermal treatment : up to 800 C in low vacuum (5*10-2 mbar), 0.5 C/min up to 1500 C in vacuum with Ar flow (1 mbar), 1 3 C/min 2 hours at 1500 C B(OH) 3 + CITRIC ACID 2.2:1 mol 1500 C 2h Vacuum+Ar C ( ) B 4 C ( ) B 4 C formation after primary thermal treatment B 4 C SINTERED SAMPLE C ( ) B 4 C ( ) HT SINTERING ( ) ( )

10 Possible p-rich beams for SPES-α 1 H 2 He 3 Li 4 Be 5 B 6 C 7 N 8 O 9 F 10 Ne 11 Na 12 Mg 13 Al 14 Si 15 P 16 S 17 Cl 18 Ar 19 K 20 Ca 21 Sc 22 Ti 23 V 24 Cr 25 Mn 26 Fe 27 Co 28 Ni 29 Cu 30 Zn 31 Ga 32 Ge 33 As 34 Se 35 Br 36 Kr 37 Rb 38 Sr 39 Y 40 Zr 41 Nb 42 Mo 43 Tc 44 Ru 45 Rh 46 Pd 47 Ag 48 Cd 49 In 50 Sn 51 Sb 52 Te 53 I 54 Xe 55 Cs 56 Ba 72 Hf 73 Ta 74 W 75 Re 76 Os 77 Ir 78 Pt 79 Au 80 Hg 81 Tl 82 Pb 83 Bi 84 Po 85 At 86 Rn 87 Fr 88 Ra 57 La 58 Ce 59 Pr 60 Nd 61 Pm 62 Sm 63 Eu 64 Gd 65 Te 66 Dy 67 Ho 68 Er 69 Tm 70 Yb 71 Lu 89 Ac 90 Th 91 Pa 92 U 93 Np 94 Pu 95 Am 96 Cm 97 Bk 98 Cf 99 Es 100 Fm 101 Md 102 No 103 Lr Alkaline - Alkaline earth metals Halogens Noble gases Post-transition elements Transition metals Lanthanides

Target for light isotopes Elemento A Half Life Target dedicati Ionizzazione SiC (Saint Gobain) Na 21 22.48 s Al 2 O 3 SiC SIS Na 22 2.

18 s SiC SIS-LIS Al 26 6.35 s SiC SIS-LIS 28 Si(p,a) 25 Al 28 Si(p,2pn) 26 Al P 29 4.

11 Target for light isotopes Elemento A Half Life Target dedicati Ionizzazione SiC (Saint Gobain) Na s Al 2 O 3 SiC SIS Na a Al 2 O 3 SiC SIS Mg s Al 2 O 3 SiC LIS-FEBIAD Mg s Al 2 O 3 SiC LIS-FEBIAD Al s SiC SIS-LIS Al s SiC SIS-LIS Al s SiC SIS-LIS 28 Si(p,a) 25 Al 28 Si(p,2pn) 26 Al P s SiC - CeS FEBIAD Elemento A Half Life Target dedicati Ionizzazione Boron Carbide Be d B 4 C LIS F s ZrO 2 HfO 2 FEBIAD F m Al 2 O 3 FEBIAD Si s Al 2 O 3 FEBIAD Si s Al 2 O 3 FEBIAD

Target for heavy isotopes Elemento A Half Life Target dedicati Ionizzazione I 126 13.11d LaCx - CeS FEBIAD LaCx Xe 127 36.

5 d LaCx - CeS SIS La 2 O 3 + 11C 2LaC 2 + 4C + 3CO Elemento A Half Life Target dedicati Ionizzazione TaC foam Ho 164 29 m TaC SIS Tm

12 Target for heavy isotopes Elemento A Half Life Target dedicati Ionizzazione I d LaCx - CeS FEBIAD LaCx Xe d CeS FEBIAD Cs h CeS SIS Cs m LaCx - CeS SIS Cs d LaCx - CeS SIS Cs d LaCx - CeS SIS Ba d LaCx - CeS SIS La 2 O C 2LaC 2 + 4C + 3CO Elemento A Half Life Target dedicati Ionizzazione TaC foam Ho m TaC SIS Tm d TaC SIS Yb d TaC SIS Lu d TaC SIS Lu a TaC SIS Lu a TaC SIS Hf h TaC FEBIAD Ta 2 O 5 + 7C 2TaC + 5CO

13 P-rich: production difficulty Target material Producible Elements Ion Source Material R&D effort needed Beam quality SiC Al, Na, Mg, P LIS-SIS-PIS *? LaC X Cs, I, Ce, Ba SIS-PIS *? B 4 C Be LIS-PIS **? ZrC As, Br, Rb, Sr SIS-PIS **? Al 2 O 3 Na, Mg, Si LIS-SIS-PIS ***? HfO2 ZrO2 F PIS ***? CeS P, Cl, La PIS ****?

14 Proton-rich RIBS at HRIBF Seven different targets used Three different ion sources 33 radioactive beams HfO 2 for 17,18 F beams 2 m CeS on RVC matrix for 34 Cl 14

15 Extrapolations for SPES (to be checked using dedicated codes..) p-rich light isotopes Elements T 1/2 Ion Source Yield (1/s) Target material 7 Be 53 d LIS-PIS ~10 9 B 4 C 17 F 65 s PIS ~10 9 HfO2 ZrO2 18 F 110 m PIS ~10 8 HfO2 ZrO2 25 Al 7 s LIS-PIS ~10 6 SiC 26 Al 6 s LIS-PIS ~10 8 SiC 27 Si 4 s LIS-PIS ~10 5 SiC 34 Cl 32 m PIS ~10 6 CeS

$Study of Isotope Yields from p->targ refractory Study of Release from p->targ$

16 What next for spes-alpha? Study of Isotope Yields from p->targ refractory Study of Release from p->targ refractory Yield Measurement of p->targ different T (LNS?)

17 The SPES-TIS group